Aseismic slip and fault‐normal strain along the central creeping section of the San Andreas fault

Rolandone, F.; Bürgmann, Roland; Agnew, Duncan Carr; Johanson, I. A.; Templeton, D. C.; d'Alessio, Matthew; Titus, Sarah; DeMets, Charles; Tikoff, Basil

doi:10.1029/2008gl034437

Cited by 52 publications

(71 citation statements)

References 22 publications

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“…As this region did not produce large earthquakes in recorded history, it likely experiences cycles of accelerated and reduced aseismic slip. Overall, the slip rates on the creeping segment are not uniform, compatible with the results of Rolandone et al [] obtained with GPS data alone and those of [ Ryder and Bürgmann , ] obtained from InSAR analysis.…”

Section: Interseismic Creep After the 2004 Mw6 Parkfield Earthquakesupporting

confidence: 87%

“…We use average velocities of surface displacement derived from analysis of continuous GPS times series and interferometric synthetic aperture radar (InSAR). Many analyses of InSAR and GPS have been successful at constraining slow interseismic deformation across faults [ Wright et al , ; Fialko , ; Cavalié et al , ; Jolivet et al , ; Elliott et al , ; Wang et al , ; Fay and Humphreys , ; Lundgren et al , ; Bell et al , ; Lindsey and Fialko , ; Jolivet et al , ], and our work extends studies focused on the northern termination of the central SAF section [ Rolandone et al , ; Ryder and Bürgmann , ; Johanson and Bürgmann , ]. Because the apparent interseismic velocity can change appreciably during the interseismic cycle [e.g., Tse and Rice , ; Lapusta et al , ; Barbot et al , ; Lapusta and Barbot , ], we compare interseismic fault slip rates before and after the 2004 Parkfield earthquake.…”

Section: Introductionsupporting

confidence: 72%

“…Shallow creep in the creeping section is higher but in some places markedly slower than plate rate at greater depths [ Thatcher , ; Johanson and Bürgmann , ; Rolandone et al , ; Ryder and Bürgmann , ]. The implications of this shallow slip deficit is not fully understood and may be the result of a process of stress buildup released in earthquakes [ Toppozada et al , ], spontaneously nonsteady fault slip due to a particular friction behavior in a manner similar to slow slip events of slow earthquakes [e.g., Rogers and Dragert , ; Liu and Rice , ; Miyazaki et al , ; Ito et al , ] or transient loading from earthquakes on neighboring segments [e.g., Ben‐Zion et al , ].…”

Section: Introductionmentioning

confidence: 99%

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Change of apparent segmentation of the San Andreas fault around Parkfield from space geodetic observations across multiple periods

2013

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Sequences of earthquakes are commonly represented as a succession of periods of interseismic stress accumulation followed by coseismic and postseismic phases of stress release. Because the recurrence time of large earthquakes is often greater than the available span of space geodetic data, it has been challenging to monitor the evolution of interseismic loading in its entire duration. Here we analyze large data sets of surface deformation at different key episodes around the Cholame, Parkfield and creeping segments of the San Andreas Fault that show evidence of significant deceleration of fault slip during the interseismic period. We compare the average fault slip rates before and after the 2004 Mw6 Parkfield earthquake, in the 1986–2004 and 2006–2012 periods, respectively, avoiding 2 years of postseismic deformation after 2004. Using a combination of GPS data from the Plate Boundary Observatory, the Southern California Earthquake Center Crustal Motion Map and the Bay Area Velocity Unification networks and interferometric synthetic aperture radar from the Advanced Land Observing Satellite (ALOS) and Envisat satellites, we show that the area of coupling at the transition between the Parkfield and Cholame segments appears larger later in the interseismic period than it does earlier on. While strong plate coupling is uniform across the Parkfield and Cholame segments in the 1986–2004 period, creep occurs south of the 2004 epicenter after 2006, making segmentation of the San Andreas Fault south of Parkfield more clearly apparent. These observations indicate that analyses of surface deformation late in the earthquake cycle may overestimate the area of plate coupling. A fault surface creeping much below plate rate may in some case be a region that does not promote earthquake nucleation but rather just be at a slower stage of its evolution. Our analysis also shows signs of large variation of slip velocity above and below plate rate in the creeping segment indicating that cycles of weakening and hardening can also be at play in dominantly aseismic areas.

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Section: Interseismic Creep After the 2004 Mw6 Parkfield Earthquakesupporting

confidence: 87%

Section: Introductionsupporting

confidence: 72%

Section: Introductionmentioning

confidence: 99%

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Change of apparent segmentation of the San Andreas fault around Parkfield from space geodetic observations across multiple periods

2013

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“…Interseismic and postseismic strain rates for four strike-slip faults where data are available before and after a major earthquake74105108125126127128. Strain rates in units of microstrain per year and are normalized by the long-term slip rate of the fault.…”

Section: Figurementioning

confidence: 99%

The role of space-based observation in understanding and responding to active tectonics and earthquakes

2016

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The quantity and quality of satellite-geodetic measurements of tectonic deformation have increased dramatically over the past two decades improving our ability to observe active tectonic processes. We now routinely respond to earthquakes using satellites, mapping surface ruptures and estimating the distribution of slip on faults at depth for most continental earthquakes. Studies directly link earthquakes to their causative faults allowing us to calculate how resulting changes in crustal stress can influence future seismic hazard. This revolution in space-based observation is driving advances in models that can explain the time-dependent surface deformation and the long-term evolution of fault zones and tectonic landscapes.

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“…The creeping section of the San Andreas fault extends north-northwest from Parkfi eld, California, to San Juan Bautista, California, and it creeps at a rate of ~3 cm/yr (Savage and Burford, 1973;Burford and Harsh, 1980;Titus et al, 2005;Rolandone et al, 2008;Ryder and Bürgmann, 2008) (Fig. 1).…”

Section: Study Areamentioning

confidence: 99%

Fault-zone controls on the spatial distribution of slow-moving landslides

Scheingross

Minchew

Mackey

et al. 2013

Geological Society of America Bulletin

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Aseismic slip and fault‐normal strain along the central creeping section of the San Andreas fault

Cited by 52 publications

References 22 publications

Change of apparent segmentation of the San Andreas fault around Parkfield from space geodetic observations across multiple periods

Change of apparent segmentation of the San Andreas fault around Parkfield from space geodetic observations across multiple periods

The role of space-based observation in understanding and responding to active tectonics and earthquakes

Fault-zone controls on the spatial distribution of slow-moving landslides

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